The Dolge njive barrow cemetery

The Early Iron Age Dolenjska group extended across south-eastern Slovenia and part of northern Croatia. The Dolge njive cemetery is one of several distributed around the large (12.68ha) hillfort at Veliki Vinji vrh, collectively constituting one of the largest Dolenjska mortuary complexes, with an estimated total of 145 barrows (Figure 1). Four main barrow groups ascend to the north-western entrance of the hillfort, with a further 45 barrows dispersed, individually or in small groups, across a wider area of more than 25km². Many of these barrows were excavated in the late nineteenth century with a relatively poor standard of recording and documentation. Modern excavations confirm, however, that skeletal remains in the area are typically very poorly preserved, if at all (Dular & Tecco Hvala Reference Dular and Tecco Hvala2007: 191; Mason & Mlekuž Reference Mason, Mlekuž and Armit2016).

Figure 1. Location of the Dolge njive cemetery (figure by the authors).

The Dolge njive cemetery is located between two deeply incised valleys at the foot of the Vinji vrh massif, to the south-east of the hillfort (Figure 2). In 2002, excavations in advance of motorway construction revealed the poorly preserved remains of three Early Iron Age barrows. Two were constructed on the site of Late Bronze Age cremation platforms, whilst the third was located a short distance to the east and is connected to the others by a Late Bronze Age hollow-way with associated deposits of cremated bone (Mason Reference Mason, Djurić and Prešeren2005; Mason & Mlekuž Reference Mason, Mlekuž and Armit2016). The remains of an Early Iron Age farmstead or small settlement, comprising two cobbled surfaces and two probable domestic structures, were discovered at Pod Vovkom to the south-west of the site (Križ Reference Križ, Djurić and Prešeren2005) (Figure 2). Its location was undoubtedly influenced by the proximity of the river Krka, but it may also have taken advantage of one of the possible routes from the valley to the hillfort.

Figure 2. Map of the complex around the Veliki Vinji vrh hillfort, with the Dolge njive cemetery (red area) and barrows (red dots) indicated (figure by the authors).

Although two of the Dolge njive barrows (2 and 3) had been largely destroyed by a combination of Roman settlement activity and medieval agriculture, both contained at least one inhumation, each accompanied by spearheads (Figure 3a; Table 1). Barrow 1, on the other hand, was better preserved and contained the remains of six graves (Figure 3b), all of which contained extended, supine inhumations, including one double burial (Burial 3) comprising two individuals buried head to toe (Table 1). Five of the graves were arranged in an approximate circle around the perimeter of the barrow, while the other (Burial 1) lay more centrally. This latter grave, however, cut the edge of Burial 3 (the double grave) and thus cannot be primary. Although central graves in the region tend to be the earliest within each barrow, exceptions are known where they belong to later or even to the latest phases of a barrow's use (e.g. Križ Reference Križ2019: 277 & 293).

Figure 3. a) Layout of the Dolge njive cemetery, indicating the presumed position of the truncated barrows (after Mason & Mlekuž Reference Mason, Mlekuž and Armit2016); b) plan of the excavated graves within Barrow 1 (figure by the authors).

Table 1. Burials from Dolge njive. Sex: F = female; M = male; U = unidentified; ? indicates uncertainty.

The limited evidence for intercutting within Barrow 1 (Figure 3b), in combination with the slight degree to which the graves intersect, appears to indicate that the later graves were laid out to respect the earlier burials. This suggests either that the earlier graves were marked on the surface and/or that the graves were dug over a relatively short period. All the graves contained grave goods, although the number and composition vary (Table 1); on typological grounds, they date mostly to the Stična (I) phase of the Dolenjska Early Iron Age chronology—that is, Hallstatt C (probably C1). Combining the dates of the grave goods with the stratigraphic and aDNA evidence (see below), we conclude that the bodies in Barrow 1 were probably deposited over a relatively short period during the early/mid seventh century BC.

Osteological analysis

The skeletal remains from the three Dolge njive barrows are characterised by cortical exfoliation and root etching, and are generally heavily fragmented and incomplete (Nicholls Reference Nicholls2017). This is particularly the case for the less dense bones of the axial skeleton (vertebrae, sterna, ribs and ossa coxae) and crania, hampering osteological assessment of age and sex. The dentition exhibits varying degrees of preservation, but survives most frequently as loose teeth, which permit age estimation. All the remains appear to belong to young (approximately 20–35 years old) and middle adults (approximately 36–50 years old). Based on skeletal morphology, we can tentatively assign sex in only five cases (Table 1). We note no pathological alterations, although this is unsurprising, given the poor preservation of the bones.

Ancient DNA analysis

We successfully analysed aDNA from all nine individuals recovered from Dolge njive: seven from Barrow 1, and a single individual each from Barrows 2 and 3. The genomic data obtained for these individuals allows us to determine genetic sex based on the ratio of Y chromosome sequences to combined X and Y chromosome sequences (Table 1), as well as maternal (mitochondrial) and paternal (Y chromosome) lineages (see the online supplementary material (OSM), which also provides information on the population genetics of the group). Regarding the mitochondrial lineages, six of the seven samples from Barrow 1 belong to the H1e5 haplogroup, while the seventh carries the H haplogroup. Individuals from Barrows 2 and 3 carry the H5a6 and H1ba haplogroups, respectively. All males (across all three barrows) carry a R1b Y chromosome haplogroup, which is one of the major Y-chromosome haplogroups in Europe following the Late Neolithic/Bronze Age transition; it became widespread in Europe during the second half of the third millennium BC and is ultimately linked to ancestry from the Eurasian steppe (Allentoft et al. Reference Allentoft2015; Haak et al. Reference Haak2015).

To explore potential genetic relationships among the Dolge njive individuals, we used the software READ (Monroy-Kuhn et al. Reference Monroy-Kuhn, Jakobsson and Günther2018). Within Barrow 1, all seven individuals are close biological relatives (Figure 4). Burial 5 represents the father of the individuals in Burials 1, 3a, 3b and 4: three brothers and a sister. The young adult female from Burial 2 is a second-degree relative of these siblings and their father; this individual is therefore most likely to be the granddaughter of the man from Burial 5 and niece of the four siblings. Since the young adult female from Burial 2 has the same mitochondrial haplogroup as the siblings, it is likely that the mother of this individual was a sister of this group. Burial 6 is a third-degree relative of the siblings (Burials 1, 3a, 3b and 4a), with whom this young adult male shares the same mitochondrial haplogroup. This individual might be their maternal cousin, mother's half-sibling, or great-uncle. The individuals interred in Barrows 2 and 3 are not close biological relatives either of each other or of the family group buried in Barrow 1.

Figure 4. Putative ‘family trees’ based on the aDNA results. In Hypothesis 1, Burial 5 is the father of Burials 1, 3a, 3b and 4, and grandfather of Burial 2. In this scenario, Burial 6 is a maternal cousin of the siblings (Burials 1, 3a, 3b and 4). In Hypothesis 2, Burial 6 is a maternal great-uncle of the siblings, while the other relationships remain unchanged (figure by the authors).

Multi-isotope analysis

We analysed multiple isotopes from the bones and teeth of all the individuals in Barrow 1 in order to examine evidence for diet and mobility (see the OSM). Where possible, we sampled multiple elements from each individual to explore intra-individual isotopic heterogeneity—that is, lifetime variability. In addition to providing information about diet and mobility, the nature of this assemblage gives a rare opportunity to examine variation in isotope ratios within a familial group.

The δ¹³C and δ¹⁵N isotope ratios for the group range from −16.6‰ to −13.6‰ and 7.9‰ to 9.5‰, respectively, indicating a terrestrial-based diet composed of a mixture of C₃ and C₄ plants with some herbivorous animal protein (Tykot Reference Tykot, Martini, Milazzo and Piacentini2004; Hedges & Reynard Reference Hedges and Reynard2007). The values of different elements from each individual show little variation (see Figure 5), indicating consumption of similar sources of terrestrial protein throughout their lives. The Δ δ¹³C_CARB-COL values consistently exceed 4‰, reflecting a diet high in C₄ carbohydrates—probably millet (cf. Lightfoot et al. Reference Lightfoot, Liu and Jones2013) (Table S1). These results are consistent with previous, albeit limited, isotopic analyses of human and archaeobotanical remains of this period in Slovenia (Murray & Schoeninger Reference Murray, Schoeninger, Gibson and Geselowitz1988; Dular & Tecco-Hvala Reference Dular and Tecco Hvala2007; Nicholls et al. Reference Nicholls2020).

Figure 5. a) Carbon isotope ratios from individuals in Barrow 1; b) nitrogen isotope ratios from individuals in Barrow 1; c) carbonate oxygen isotope ratios against strontium isotope ratios obtained from the tooth enamel. Analytical precision based on instrumental error of ±0.2‰ (too small to be visible on the chart) (figure by the authors).

Strontium results are variable, with ⁸⁷Sr/⁸⁶Sr ranging from 0.7091 to 0.7102, with concentrations between 59 and 226ppm (Table S3; Figures 5b & 6). The δ¹⁸O_CARB isotope ratios occupy a relatively narrow range of 21.1‰ to 22.8‰. The ⁸⁶Sr/⁸⁷Sr values are consistent with the variable local geology, with no evidence for childhood mobility.

Figure 6. ⁸⁷Sr/⁸⁶Sr plotted against strontium concentration for individuals in Barrow 1 (figure by the authors).

Strontium concentrations may reflect the trophic level of food consumed by an individual, decreasing in value with increasing trophic level (Evans et al. Reference Evans, Chenery and Fitzpatrick2006). The wide variation in strontium concentrations here suggests that two of the brothers (Burials 3a and 4) consumed more meat and dairy than the other individuals, while their father (Burial 5) exhibits by far the highest Sr concentration, and thus appears to have consumed a diet with a larger proportion of lower-trophic level food (Table S3; Figure 6). This is consistent with the latter's δ¹⁵N values, which are the lowest among the group in terms of both dentine and rib collagen. The tooth enamel sampled for this analysis reflects the Sr, O and C_CARB isotopic compositions of food consumed during the formation of the tooth crown in early childhood. It appears, therefore, that the father (Burial 5) consumed a different childhood diet and/or lived in a different location compared with his children.

Sex identification from aDNA, osteology and grave goods

There has been much criticism regarding the traditional methodological basis of ascribing sex based on grave goods, particularly in the absence of secure osteological identification (e.g. Arnold Reference Arnold1996). For the Early Iron Age Dolenjska region, however, Teržan (Reference Teržan1985) has proposed that gendered grave goods are a reliable guide to the biological sex of the interred individual. It is therefore appropriate to consider how the sex estimations provided by osteological analysis and aDNA analysis here compare with those suggested by the grave goods.

The regional artefact typology makes it possible to attribute gender to, and therefore to infer biological sex of, six individuals from the three Dolge njive barrows (Table 1). In Barrow 1, Burials 1 and 2 were associated with distinct female attire. The Libna-style belt from Burial 3 is characteristic of typologically male graves (Guštin & Preložnik Reference Guštin and Preložnik2005); since this grave contained two burials (the belt seems to have tied both bodies together), it suggests that at least one male is present. Similarly, the presence of two iron spearheads in Burial 4 suggests that this individual is male. Spearheads also accompanied both individuals identified in the other two (damaged) barrows, suggesting that these individuals are also male. All six attributions based on grave goods (Burials 1, 2, 3a and 4 in Barrow 1, and those in Barrows 2 and 3) are independently confirmed by the aDNA analysis. Given the poor preservation of the skeletal remains, only tentative sex estimations were possible; when compared with the aDNA results, three out of five cases of these tentative attributions prove incorrect (see Table 1).

AMS dating

Six AMS radiocarbon dates were obtained from the skeletal remains: one from each of the graves in Barrow 1 (Table 2; Figure 7). The results form a consistent series in the period c. 800–540 cal BC. The radiocarbon calibration problems associated with the Hallstatt plateau, however, are such that the AMS dates remain highly imprecise and are not readily amenable to further resolution through Bayesian analysis. They are, nonetheless, consistent with the typological dates for the grave goods, which suggest deposition in the first half of or mid seventh century BC.

Figure 7. AMS dates from Barrow 1, plotted using OxCal v4.4 (Bronk Ramsey Reference Bronk Ramsey2017) and IntCal 2020 (Reimer et al. Reference Reimer2020) (figure by the authors).

Table 2. AMS dates from Barrow 1: all dates on human bone.